JP2023080727A - Construction machine - Google Patents

Abstract

To provide a construction machine allowing an electromagnetic valve for lifting a boom to be protected from impact from outside acting on a vehicle body.SOLUTION: A hydraulic shovel 1 is provided with: a revolving frame 6; a control valve 20 mounted on the revolving frame 6 and controlling a hydraulic flow supplied to a hydraulic actuator; an electrical operating device operated upon controlling the hydraulic actuator; and an electromagnetic valve device 23 controlling the control valve 20 based on an electrical signal from the electrical operating device. The hydraulic actuator comprises a boom cylinder 5D revolving a boom 5A of a work device 5 in a vertical direction regarding a super structure 4, the electrical valve device 23 comprises a plurality of electrical valves including an electromagnetic valve 25 making the boom cylinder 5D lift the boom 5A, and the electromagnetic valve 25 for lifting the boom is placed at a position overlapping a right side frame 9 in a side view in a state the electromagnetic valve device 23 is mounted on the revolving frame 6.SELECTED DRAWING: Figure 7

Description

TECHNICAL FIELD The present disclosure relates to a construction machine such as a hydraulic excavator equipped with an electric operating device that controls the operation of a hydraulic actuator.

A hydraulic excavator, which is a representative example of construction machinery, includes a self-propelled lower traveling body, an upper revolving body mounted on the lower traveling body so as to be able to turn via a revolving device, and a working device provided on the upper revolving body. , and a plurality of hydraulic actuators. Hydraulic actuators mounted on the hydraulic excavator include a travel actuator configured by a travel hydraulic motor provided on the lower travel body, a swing hydraulic motor provided on the swing device, and a plurality of hydraulic actuators provided on the work device. It is roughly classified into a working actuator consisting of a cylinder. The upper slewing structure is provided with a travel operation device and a work operation device operated by an operator. By controlling the operation of various hydraulic actuators according to the operation of these operation devices, excavation using a hydraulic excavator is performed. Work is done.

In recent years, due to the decrease in the number of skilled operators, labor saving at construction sites and semi-automation technology for construction machinery have become widespread. A hydraulic excavator equipped with an operating device is employed. As a hydraulic excavator equipped with such an electric operation device, there is a hydraulic excavator (Patent Document 1) in which both the operation device for traveling and the operation device for work are electric operation devices, and the operation device for work is an electric operation device. A hydraulic excavator (Patent Document 2) has been proposed in which an operating device is configured and a traveling operating device is configured by a hydraulic operating device.

Hydraulic excavators equipped with electric operating devices are equipped with control valves that control the flow of pressure oil supplied to multiple hydraulic actuators, as well as electrical components such as solenoid valve devices, solenoid valve controllers, and cables. there is The solenoid valve controller calculates a target valve opening degree of the solenoid valve according to the operation of the electric operating device, and outputs an electric signal corresponding to the target value to the solenoid valve device. The solenoid valve device is composed of a plurality of solenoid valves (proportional solenoid valves), and controls pilot pressure supplied to a plurality of directional control valves that constitute control valves based on electrical signals from a solenoid valve controller.

Here, the working device of a hydraulic excavator usually includes a boom attached to an upper revolving structure, an arm attached to the tip of the boom, a bucket attached to the tip of the arm, and a boom cylinder and an arm, which are hydraulic actuators. It includes a cylinder and a bucket cylinder. The solenoid valve device includes a plurality of solenoid valves including a boom solenoid valve for operating the boom by the boom cylinder, an arm solenoid valve for operating the arm by the arm cylinder, and a bucket solenoid valve for operating the bucket by the bucket cylinder. It is

JP 2012-72636 A JP 2016-142285 A

During operation of the hydraulic excavator, there is a possibility that the solenoid valve device will be damaged due to collision with surrounding obstacles such as rocks, collision with falling rocks, and the like. If the solenoid valve device is damaged, it becomes impossible to normally operate the hydraulic actuator using the electric operating device. In particular, if the solenoid valve device is damaged during excavation work (while the tip (bucket) of the work equipment is at a position lower than the ground), the tip of the work equipment will stop in a state where it is caught on the ground. As a result, it is no longer possible to drive the excavator by itself or use a towing vehicle to move the excavator, making it difficult to transport the excavator to a repair shop and quickly repair the damaged solenoid valve device. There is a problem of becoming

It is an object of the present invention to provide a construction that can be quickly moved by itself or by a towing vehicle even if it collides with an obstacle such as a surrounding rock during excavation work or collides with falling rocks. It is to provide the machine.

The present invention includes a self-propellable vehicle body, a working device provided on the vehicle body, and a plurality of hydraulic actuators for driving at least the working device, and the vehicle body includes a vehicle body frame as a base and a hydraulic pump. A control valve for controlling the flow of pressure oil supplied to the plurality of hydraulic actuators, an electric operating device for outputting an electric signal according to the operation, and the control valve based on the electric signal from the electric operating device wherein the body frame has a center frame extending in the front-rear direction and side frames arranged on both left and right sides of the center frame, wherein the plurality of hydraulic actuators includes a boom actuator that vertically rotates a boom that constitutes a part of the work device with respect to the vehicle body, and the electromagnetic valve device causes the boom actuator to lift the boom. It is composed of an assembly of a plurality of solenoid valves including a boom raising solenoid valve, and the boom raising solenoid valve is arranged at a position overlapping with the side frame in a side view.

According to the present invention, the solenoid valve device including the boom raising solenoid valve can be protected even when there is a collision with an obstacle such as a surrounding bedrock or a collision with falling rocks. As a result, the boom can be lifted to prevent the working device from being caught on the ground, so that the vehicle body can be moved quickly by self-propelled or by a towing vehicle.

1 is a left side view showing a hydraulic excavator according to an embodiment of the present invention; FIG. Fig. 2 is a plan view of the hydraulic excavator viewed from above; FIG. 4 is a top plan view of the revolving frame on which the control valve and the electromagnetic valve device are mounted; It is a perspective view showing a control valve, an electromagnetic valve device, and a valve bracket. It is a perspective view which shows a revolving frame, a control valve, and an electromagnetic valve apparatus. 3 is a perspective view showing a revolving frame, control valves, an electromagnetic valve device, a valve cover, and an opening/closing cover; FIG. FIG. 6 is a cross-sectional view of the bottom plate, right side frame, electromagnetic valve device, etc., viewed in the direction of arrows VII-VII in FIG. 5; 1 is a system configuration diagram including an electric operating device, a solenoid valve controller, a solenoid valve device, a control valve, etc. according to the first embodiment; FIG. FIG. 4 is a system configuration diagram when an external controller is used to drive a boom raising solenoid valve; FIG. 7 is a system configuration diagram including a hydraulic operating device, an electric operating device, a solenoid valve controller, a solenoid valve device, a control valve, etc. according to a second embodiment;

Hereinafter, a case where a construction machine according to an embodiment of the present invention is applied to a crawler hydraulic excavator will be described in detail with reference to FIGS. 1 to 10. FIG. In the embodiments, the traveling direction of the hydraulic excavator is defined as the front-rear direction, and the direction perpendicular to the traveling direction is defined as the left-right direction.

1 to 9 show a first embodiment. A hydraulic excavator 1 shown in FIG. 1 includes a crawler-type lower running body 2 capable of self-propelled in the longitudinal direction, and an upper revolving body 4 mounted on the lower running body 2 via a revolving device 3 so as to be able to turn. ing. A vehicle body of the hydraulic excavator 1 is composed of a lower running body 2 and an upper revolving body 4 . The lower traveling body 2 has a left traveling motor 2A and a right traveling motor 2B as hydraulic actuators for traveling. The left traveling motor 2A drives the left crawler 2C and the right traveling motor 2B drives the right crawler 2D. , run on uneven ground, etc. A working device 5 is provided on the front side of the upper revolving body 4, and the working device 5 is used to perform earth and sand excavation work.

The working device 5 includes a boom 5A rotatably attached to a left vertical plate 7B and a right vertical plate 7C of a revolving frame 6, which will be described later, an arm 5B rotatably attached to the tip of the boom 5A, and an arm 5B. and a bucket 5C rotatably attached to the tip of the. As working hydraulic actuators for driving the working device 5, there are two boom cylinders 5D (boom actuators) for rotating the boom 5A, an arm cylinder 5E for rotating the arm 5B, and a bucket 5C for rotating. and a bucket cylinder 5F.

The upper revolving body 4 is mounted on the lower traveling body 2 via a revolving device 3 so as to be able to revolve. The swing device 3 is provided with a swing motor 3A as a working hydraulic actuator. By rotationally driving the turning motor 3A, the upper turning body 4 performs a turning motion on the lower traveling body 2. As shown in FIG. The upper revolving body 4 has a revolving frame 6 as a base, and the revolving frame 6 is equipped with a counterweight 10, an engine 11, a hydraulic pump 12, a cab 14, an exterior cover 18, a control valve 20, an electromagnetic valve device 23, and the like. It is

A swivel frame 6 as a vehicle body frame is attached to the undercarriage 2 via a swivel device 3 . As shown in FIG. 3 , the revolving frame 6 includes a center frame 7 arranged in the center in the left-right direction and extending in the front-rear direction, a left side frame 8 arranged on the left side of the center frame 7 , and a left side frame 8 arranged on the right side of the center frame 7 . It is roughly constituted by the right side frame 9 arranged.

The center frame 7 has a thick flat bottom plate 7A, and a left vertical plate 7B and a right vertical plate 7C erected on the bottom plate 7A. The left vertical plate 7B and the right vertical plate 7C extend in the front-rear direction while being opposed to each other at a constant interval in the left-right direction. A boom mounting portion 7D and a boom cylinder mounting portion 7E are provided on the front end sides of the left vertical plate 7B and the right vertical plate 7C. A base end portion (boom foot portion) of the boom 5A is pin-connected to the boom mounting portion 7D so as to be vertically rotatable, and a bottom side of the boom cylinder 5D is vertically rotatably mounted to the boom cylinder mounting portion 7E. Pinned. On the other hand, a counterweight 10 is attached to the rear end sides of the left vertical plate 7B and the right vertical plate 7C. The counterweight 10 maintains a weight balance with the work device 5. - 特許庁

The center frame 7 is provided with a plurality of left projecting beams 7F projecting leftward from the bottom plate 7A and the left vertical plate 7B, and a plurality of right projecting beams 7G projecting rightward from the bottom plate 7A and the right vertical plate 7C. ing. A left side frame 8 is attached to the tip of the left overhanging beam 7F, and a right side frame 9 is attached to the tip of the right overhanging beam 7G.

The left side frame 8 is arranged on the left side of the center frame 7 . The left side frame 8 is made of a strong pipe body having a D-shaped cross section. The left side frame 8 is attached to the ends of a plurality of left projecting beams 7F projecting from the center frame 7, and extends in the front-rear direction along the center frame 7 (left vertical plate 7B). An L-shaped front cab support member 8A is provided between the front end of the left side frame 8 and the left vertical plate 7B, and is located between the longitudinally intermediate portion of the left side frame 8 and the left vertical plate 7B. is provided with a rear cab support member 8B.

The right side frame 9 is arranged on the right side of the center frame 7 . The right side frame 9 is formed using a pipe body having a D-shaped cross section and excellent strength, and is attached to the ends of a plurality of right projecting beams 7</b>G projecting from the center frame 7 . The right side frame 9 has a right frame portion 9A extending in the longitudinal direction along the center frame 7 (right vertical plate 7C), and a right front frame portion 9B bent from the front end of the right frame portion 9A toward the center frame 7. are doing. The tip (left end) of the right front frame portion 9B is connected to the right vertical plate 7C of the center frame 7 .

A fuel tank 16 and a hydraulic oil tank 17 are mounted on two right overhanging beams 7G that connect the center frame 7 and the right side frame 9 together. A flat valve support plate 9D fixed to the bottom plate 7A and the right side frame 9 by means of welding or the like is provided inside the right front corner portion 9C where the right frame portion 9A and the right front frame portion 9B intersect. there is The upper surface of the valve support plate 9D forms the same plane as the upper surface of the bottom plate 7A of the center frame 7, and the valve support plate 9D supports the control valve 20, the solenoid valve device 23, and the like.

An engine 11 as a prime mover is positioned in front of the counterweight 10 and mounted on the revolving frame 6 . The engine 11 is supported on the rear end sides of the left vertical plate 7B and the right vertical plate 7C of the center frame 7 via anti-vibration mounts (not shown). The engine 11 is mounted on the revolving frame 6 in a horizontal position with a crankshaft extending in the left-right direction, and rotationally drives the hydraulic pump 12 and the pilot pump 13 (see FIG. 8).

The cab 14 is arranged on the front left side of the revolving frame 6 . The cab 14 is formed in the shape of a box with an interior serving as an operator's cab. (not shown). Inside the cab 14 defined by the cab 14 are a driver's seat 15 in which an operator sits, a left travel operation device 29 and a right travel operation device 30 which are arranged in front of the driver's seat 15, and the driver's seat 15. A left work operation device 31 and a right work operation device 32, which will be described later, are arranged on both left and right sides.

A fuel tank 16 and a hydraulic oil tank 17 are provided on the right side of the revolving frame 6 in front of the hydraulic pump 12 . These fuel tank 16 and hydraulic oil tank 17 are supported by two right overhanging beams 7G connecting between the center frame 7 and the right side frame 9. As shown in FIG. Fuel to be supplied to the engine 11 is stored in the fuel tank 16 , and hydraulic fluid to be supplied to various hydraulic actuators mounted on the hydraulic excavator 1 is stored in the hydraulic oil tank 17 .

The exterior cover 18 is arranged on the front side of the counterweight 10 and covers the engine 11, the hydraulic pump 12, the control valve 20, the electromagnetic valve device 23, and the like. The exterior cover 18 includes an upper surface cover 18A, a left side cover 18B, a right side cover 18C, a right front cover 18D, and a right front side cover 18E. The top cover 18A is arranged between the cab 14, the fuel tank 16, the hydraulic oil tank 17 and the counterweight 10, and covers the engine 11, the hydraulic pump 12 and the like from above. The left side cover 18B extends downward from the left end of the top cover 18A and covers the engine 11, heat exchanger (not shown), etc. from the left side. The right side cover 18C extends downward from the right end of the top cover 18A and covers the hydraulic pump 12 and the like from the right side.

The right front cover 18</b>D is arranged on the right side of the working device 5 and extends from the front ends of the fuel tank 16 and the hydraulic oil tank 17 to the right front frame portion 9</b>B of the right side frame 9 . The right front cover 18D defines a valve accommodation chamber 19 together with the right front side cover 18E, and the valve accommodation chamber 19 accommodates a control valve 20, an electromagnetic valve device 23, and the like. The right front cover 18D covers the valve housing chamber 19 from the front and above, and a plurality of steps 18F are provided on the front surface of the right front cover 18D to serve as footholds for the operator to climb onto the upper revolving body 4.

The right front side cover 18E as an opening/closing cover is arranged on the right side of the right front cover 18D and defines the valve housing chamber 19 together with the right front cover 18D. The rear end side of the right front side cover 18E is attached to a support member provided on the revolving frame 6 via a hinge mechanism (both not shown). As a result, the right front side cover 18E rotates in the front-rear direction about the hinge mechanism to open the valve accommodating chamber 19 and expose the solenoid valve device 23 and the like to the outside (position shown in FIG. 5). It moves (opens and closes) between the closed position (the position in FIG. 2) where the valve device 23 and the like are accommodated in the valve accommodating chamber 19 .

Next, the control valve 20, the electromagnetic valve device 23, etc. used in this embodiment will be described with reference to FIGS.

The control valve 20 is mounted on the valve support plate 9</b>D of the right side frame 9 via a mounting seat 21 . The control valve 20 is constructed as an assembly of a valve casing 20A and a plurality of directional control valves incorporated in the valve casing 20A. The control valve 20 is arranged inside the right front corner portion 9C of the right side frame 9 and is housed in the valve housing chamber 19 by closing the right front side cover 18E.

The plurality of directional control valves that constitute the control valve 20 include a directional control valve for the left travel motor 2A that controls the flow of pressure oil supplied to the left travel motor 2A, and a direction control valve that controls the flow of pressure oil supplied to the right travel motor 2B. A directional control valve for the right travel motor 2B that controls the flow, a directional control valve for the swing motor 3A that controls the flow of pressure oil supplied to the swing motor 3A, and directions for various cylinders that make up the work device 5. and a control valve. The directional control valves for cylinders are a directional control valve for the boom cylinder 5D that controls the flow of pressure oil supplied to the boom cylinder 5D of the work device 5, and a directional control valve that controls the flow of pressure oil supplied to the arm cylinder 5E. It is composed of a directional control valve for the arm cylinder 5E and a directional control valve for the bucket cylinder 5F that controls the flow of pressure oil supplied to the bucket cylinder 5F.

A pressure oil inlet provided in the control valve 20 is connected to the hydraulic pump 12, and a plurality of directional control valves (a directional control valve for the left traveling motor 2A, a directional control valve for the right traveling motor 2B, and a directional control valve for the right traveling motor 2B) that constitute the control valve 20 are connected. directional control valve for the swing motor 3A, directional control valve for the boom cylinder 5D, directional control valve for the arm cylinder 5E, directional control valve for the bucket cylinder 5F) correspond via hydraulic lines 22, respectively. Connected to the hydraulic actuator.

A plurality of directional control valves that constitute the control valve 20 each have a hydraulic pilot section, and control the flow of pressure oil supplied from the hydraulic pump 12 to the hydraulic actuators according to the pilot pressure supplied from the pilot pump 13. do. Here, the directional control valve for the left travel motor 2A and the directional control valve for the right travel motor 2B each have two hydraulic pilot portions for forward travel and reverse travel. The directional control valve for the swing motor 3A has two hydraulic pilot portions for left swing and right swing. Also, the directional control valve for the boom cylinder 5D has two hydraulic pilot sections for boom raising and boom lowering. The directional control valve for the arm cylinder 5E has two hydraulic pilot parts for cloud and dump. The directional control valve for the bucket cylinder 5F has two hydraulic pilot parts for cloud and dump.

The solenoid valve device 23 is arranged on the front side of the boom mounting portion 7D of the left vertical plate 7B and the right vertical plate 7C that constitute the revolving frame 6, and is mounted on the valve support plate 9D of the right side frame 9 via the valve bracket 24. is provided in The solenoid valve device 23 has two rectangular parallelepiped valve casings 23A and 23B extending in the vertical direction. (multiple valve). A plurality of electromagnetic valves provided in the valve casings 23A and 23B are stacked vertically in a plurality of stages. Also, the valve casings 23A and 23B are arranged in the front-rear direction so that the valve casing 23B is on the rear side. Thus, the plurality of electromagnetic valves provided in the valve casings 23A and 23B are arranged in two rows in the longitudinal direction of the vehicle body.

The valve bracket 24 has a bottom plate portion 24A attached to the valve support plate 9D, and a pair of rising plate portions 24B rising upward from the bottom plate portion 24A and facing each other with a gap in the front-rear direction. The solenoid valve device 23 is mounted on the bottom plate portion 24A of the valve bracket 24, and is mounted on the valve support plate 9D via the valve bracket 24 while being sandwiched from the front and rear by the pair of rising plate portions 24B. there is

Thus, the solenoid valve device 23 is composed of an assembly of a plurality of solenoid valves (proportional solenoid valves) provided in two valve casings 23A and 23B, and a plurality of directional control valves constituting the control valve 20. The pilot pressure from the pilot pump 13 is selectively supplied to the hydraulic pilot portion provided in the . Specifically, the solenoid valve device 23 includes a left travel motor solenoid valve, a right travel motor solenoid valve, a swing motor solenoid valve, a boom solenoid valve, an arm solenoid valve, and a bucket solenoid valve. and is configured as a multiple valve.

Here, the left travel solenoid valve corresponds to two hydraulic pilot portions provided in the directional control valve for the left travel motor 2A, and the forward travel solenoid valve rotates the left travel motor 2A forward. It is composed of a reverse solenoid valve that rotates 2A backward. The right travel solenoid valve corresponds to the two hydraulic pilot portions provided in the directional control valve for the right travel motor 2B. It is composed of a reverse solenoid valve that rotates. The turning solenoid valve corresponds to the two hydraulic pilot units provided in the direction control valve for the turning motor. It is composed of a turning solenoid valve.

The boom solenoid valve corresponds to the two hydraulic pilot portions provided in the directional control valve for the boom cylinder 5D, and the boom raising solenoid valve 25 (Fig. 7) causes the boom cylinder 5D to lift the boom 5A. ), and a boom lowering electromagnetic valve that causes the boom cylinder 5D to lower the boom 5A. The boom raising solenoid valve 25 is provided in the valve casing 23B located on the rear side in the front-rear direction of the two valve casings 23A and 23B that constitute the solenoid valve device 23 . That is, the boom raising solenoid valve 25 is arranged behind the other solenoid valves that constitute the solenoid valve device 23 .

The arm solenoid valve corresponds to the two hydraulic pilot portions provided in the direction control valve for the arm cylinder 5E, and the arm crowd solenoid valve that causes the arm cylinder 5E to perform the arm crowding operation of the arm 5B and the arm cylinder 5E. and an arm dump electromagnetic valve for causing the dump operation of the arm 5B. The bucket solenoid valve corresponds to the two hydraulic pilot parts provided in the directional control valve for the bucket cylinder 5F, and the bucket cloud solenoid valve for causing the bucket cylinder 5F to perform the cloud operation of the bucket 5C, and the bucket cylinder 5F. and a bucket dump solenoid valve for causing the bucket 5C to dump.

Thus, the electromagnetic valve device 23 is composed of an assembly of a plurality of electromagnetic valves including the boom raising electromagnetic valve 25 that causes the boom cylinder 5D to lift the boom 5A. A pilot pressure inflow port provided in the solenoid valve device 23 is connected to the pilot pump 13, and the plurality of solenoid valves that constitute the solenoid valve device 23 are operated in the corresponding direction among the plurality of directional control valves that constitute the control valve 20. Each is connected via a pilot line 26 to the hydraulic pilot section of the control valve.

Here, among the plurality of solenoid valves that constitute the solenoid valve device 23, the boom raising solenoid valve 25 is more important than the other solenoid valves. For example, when the hydraulic excavator 1 is in operation, there is a possibility that the electromagnetic valve device will be damaged due to a collision with an obstacle such as a surrounding bedrock, a collision with falling rocks, or the like. At this time, if the boom raising solenoid valve 25 is damaged while the tip of the bucket 5C is at a position lower than the ground, the tip of the bucket 5C cannot be lifted above the ground. In this case, since the bucket 5C stops in a state of being caught on the ground, the hydraulic excavator 1 cannot be moved by itself nor can it be moved by using a towing vehicle, and the hydraulic excavator 1 can be quickly brought to a repair shop or the like. Difficult to transport. Therefore, the boom raising solenoid valve 25 needs to be arranged at a location where the risk of damage due to external impact is low.

Therefore, the boom raising solenoid valve 25 is arranged at a position overlapping the right side frame 9 that constitutes the revolving frame 6 in a side view from the direction of arrow A in FIG. 7 . Specifically, when the solenoid valve device 23 is mounted on the revolving frame 6 , the boom raising solenoid valve 25 is arranged at a height position that intersects a horizontal plane passing through the upper end 9</b>E of the right side frame 9 . In this embodiment, the vertical range in which the boom raising solenoid valve 25 is arranged is set as follows. That is, the height dimension from the upper surface of the bottom plate 7A of the center frame 7 to the lower end 25A of the boom raising solenoid valve 25 is H1, and the height dimension from the upper surface of the bottom plate 7A of the center frame 7 to the upper end 9E of the right side frame 9 is H1. is set to H2, the height dimension H1 is set to be equal to or less than the height dimension H2 (H1≤H2).

In this way, by arranging the boom raising solenoid valve 25 at a position overlapping the right side frame 9 of the revolving frame 6 in a side view, external impacts due to collisions with obstacles, falling rocks, etc. Even if the revolving body 4 is acted upon, the right side frame 9, which is a strength member, can protect the boom raising solenoid valve 25. FIG.

Moreover, the boom raising solenoid valve 25 constitutes the solenoid valve device 23, and of the two valve casings 23A and 23B arranged in two rows in the longitudinal direction of the vehicle body, the valve casing 23B located on the rear side of the two rows. located inside. As a result, the boom raising solenoid valve 25 is arranged at a position farther from the right front frame portion 9B of the right side frame 9 than the other solenoid valves provided in the valve casing 23A. Therefore, even if an impact due to falling rocks or the like acts on the front side of the upper rotating body 4 during excavation work, the right front frame portion 9B and other solenoid valves arranged in front of the boom raising solenoid valve 25 will generate a boom raising electromagnetic wave. The valve 25 can be protected.

Further, the electromagnetic valve device 23 is arranged inside a right front corner portion 9C where the right frame portion 9A and the right front frame portion 9B of the right side frame 9 intersect. The right frame portion 9A has high strength against forces acting in the front-rear direction, and the right front frame portion 9B has high strength against forces acting in the left-right direction. Therefore, the right front corner portion 9C of the right side frame 9 has a high strength against external impact, and can protect the solenoid valve device 23 arranged inside the right front corner portion 9C with a high strength. can.

A valve storage chamber 19 defined by a right front cover 18D and a right front side cover 18E is provided on the right front side of the upper swing body 4. In the valve storage chamber 19, a control valve 20 and an electromagnetic valve device 23 are provided. is accommodated. The right front side cover 18E has an open position (position shown in FIG. 5) in which the valve accommodating chamber 19 is opened to expose the electromagnetic valve device 23 and the like to the outside, and an open position (position shown in FIG. 5) in which the electromagnetic valve device 23 and the like are accommodated in the valve accommodating chamber 19. It moves to and from the closed position (position in Figure 2). Therefore, by closing the right front side cover 18E, the electromagnetic valve device 23 can be protected from flying stones during excavation work, and by opening the right front side cover 18E, maintenance of the electromagnetic valve device 23 can be performed. workability can be improved.

Moreover, the solenoid valve device 23 is configured as an aggregate of a plurality of solenoid valves for controlling the operations of a plurality of hydraulic actuators mounted on the hydraulic excavator 1, and is collectively arranged inside the right front corner portion 9C of the right side frame 9. It is Therefore, compared to the case where a plurality of solenoid valves are arranged individually on the revolving frame, for example, the workability when installing the solenoid valve device 23 can be enhanced. Further, for example, when performing maintenance on any one of a plurality of solenoid valves, by opening the right front side cover 18E and accessing the solenoid valve device 23, maintenance of the target solenoid valve can be performed quickly. can be done.

The solenoid valve controller 27 is electrically connected to a plurality of solenoid valves forming the solenoid valve device 23 via cables 28 . The input side of the electromagnetic valve controller 27 is electrically connected to a left travel operating device 29, a right traveling operating device 30, a left working operating device 31, and a right working operating device 32 as electric operating devices. ing.

The left travel operation device 29 and the right travel operation device 30 are located in the cab 14 and provided in front of the driver's seat 15, and are arranged to face each other in the left-right direction. The left travel operation device 29 has a lever pedal 29A that is tilted in the front-rear direction when driving the left travel motor 2A. The left travel operating device 29 outputs an electric signal corresponding to the operating direction and operating amount of the lever pedal 29A to the electromagnetic valve controller 27 via the cable 29B. The right travel operating device 30 has a lever pedal 30A that is tilted in the front-rear direction when driving the right travel motor 2B. The right travel operation device 30 outputs an electric signal corresponding to the direction and amount of operation of the lever pedal 30A to the electromagnetic valve controller 27 via the cable 30B.

The left work operation device 31 is located inside the cab 14 and provided on the left side of the driver's seat 15 . The left operation operating device 31 has a lever 31A that is tilted in the left-right direction and in the front-rear direction. When doing so, the tilting operation is performed in the front-rear direction. The left work operation device 31 outputs an electric signal corresponding to the operation direction and operation amount of the lever 31A to the electromagnetic valve controller 27 via the cable 31B.

The right operation operating device 32 is located inside the cab 14 and provided on the right side of the driver's seat 15 . The right operation device 32 has a lever 32A that is tilted in the left-right direction and in the front-rear direction. For example, when the bucket cylinder 5F is driven, the lever 32A is tilted in the left-right direction to drive the boom cylinder 5D. When doing so, the tilting operation is performed in the front-rear direction. The right operation operating device 32 outputs an electric signal corresponding to the operating direction and operating amount of the lever 32A to the solenoid valve controller 27 via the cable 32B.

The electromagnetic valve controller 27 controls the operation of the left travel operation device 29, the right travel operation device 30, the left work operation device 31, and the right work operation device 32 according to the operation direction and the operation amount (operation angle). Based on the signal, the target value of the opening degree (valve opening degree) of the electromagnetic valve constituting the electromagnetic valve device 23 is calculated. Then, the electromagnetic valve controller 27 increases or decreases the current value output to the electromagnetic pilot portion of the electromagnetic valve according to the calculated target value, and adjusts the valve opening degree of the electromagnetic valve, thereby configuring the control valve 20. Controls the pilot pressure supplied to the hydraulic pilot section of the control valve.

Accordingly, the rotation direction and number of rotations of the left travel motor 2A are controlled according to the operation of the lever pedal 29A of the left travel operating device 29, and the right travel motor 2A is controlled according to the operation of the right travel operating device 30 to the lever pedal 30A. The rotation direction and number of rotations of the travel motor 2B are controlled. In addition, according to the operation of the lever 31A of the left work operation device 31, the rotation direction and rotation speed of the turning motor 3A are controlled, and the expansion/contraction direction and expansion/contraction amount of the arm cylinder 5E are controlled. Furthermore, according to the operation of the lever 32A of the right work operation device 32, the direction and amount of expansion and contraction of the bucket cylinder 5F are controlled, and the direction and amount of expansion and contraction of the boom cylinder 5D are controlled.

The hydraulic excavator 1 according to the present embodiment has the configuration as described above. Manipulate. The left travel operating device 29 outputs an electric signal to the solenoid valve controller 27 in response to the operation of the lever pedal 29A, and the right travel operating device 30 outputs an electric signal to the electromagnetic valve controller 27 in response to the operation of the lever pedal 30A. output to The solenoid valve controller 27 adjusts the opening degrees of the left travel motor solenoid valve and the right travel motor solenoid valve that constitute the solenoid valve device 23 based on the electric signals from the left travel operation device 29 and the right travel operation device 30 . Calculate the target value of (valve opening).

Then, the solenoid valve controller 27 increases or decreases the current value output to the solenoid pilot portions of the left travel motor solenoid valve and the right travel motor solenoid valve according to the calculated target value of the valve opening. As a result, the opening degrees of the solenoid valve for the left travel motor and the solenoid valve for the right travel motor are adjusted. and the pilot pressure supplied to the hydraulic pilot portion of the directional control valve for the right travel motor 2B.

As a result, the rotation direction and number of rotations of the left travel motor 2A are controlled according to the operation of the left travel operation device 29 (lever pedal 29A), and the right travel operation device 30 (lever pedal 30A) is operated. , the direction of rotation and the number of rotations of the right travel motor are controlled. As a result, the left crawler 2C and the right crawler 2D of the lower traveling body 2 are driven, and the excavator 1 can travel toward the work site.

After the hydraulic excavator 1 travels to the work site, the operator operates the lever 31A of the left operation device 31 and the lever 32A of the right operation device 32 . The left work operation device 31 outputs an electric signal to the electromagnetic valve controller 27 in response to the operation of the lever 31A, and the right work operation device 32 outputs to the electromagnetic valve controller 27 an electric signal in response to the operation of the lever 32A. do. The solenoid valve controller 27 controls the swing motor solenoid valve, the boom solenoid valve, the arm solenoid valve, Calculates the target valve opening of the bucket solenoid valve.

Then, the solenoid valve controller 27 outputs current values to the solenoid pilot portions of the swing motor solenoid valve, the boom solenoid valve, the arm solenoid valve, and the bucket solenoid valve according to the calculated target value of the valve opening. increase or decrease As a result, the opening degrees of the swing motor solenoid valve, the boom solenoid valve, the arm solenoid valve, and the bucket solenoid valve are adjusted. The pilot pressure supplied to each hydraulic pilot portion of the valve, the directional control valve for the boom cylinder 5D, the directional control valve for the arm cylinder 5E, and the directional control valve for the bucket cylinder 5F is controlled.

As a result, the rotation direction and number of revolutions of the turning motor 3A are controlled, and the expansion/contraction operation and expansion/contraction amount of the arm cylinder 5E are controlled according to the operation of the left operation operating device 31 (lever 31A). Further, according to the operation of the right operation device 32 (lever 32A), the telescopic motion and the telescopic amount of the boom cylinder 5D are controlled, and the telescopic motion and the telescopic amount of the bucket cylinder 5F are controlled. In this manner, excavation work or the like can be performed using the work device 5 while rotating the upper rotating body 4 .

During operation of the hydraulic excavator 1, there is a possibility that electrical components such as the solenoid valve controller 27 may be damaged due to external impact such as collision with an obstacle or falling rocks acting on the upper revolving body 4 . Since the hydraulic excavator 1 cannot operate normally when electrical components such as the electromagnetic valve controller 27 are damaged, the hydraulic excavator 1 must be loaded on a trailer or the like and transported to a repair shop or the like. If the electrical equipment is damaged while the work device 5 is above the ground, the hydraulic excavator 1 can be self-propelled to the trailer or the hydraulic excavator 1 can be moved to the trailer by using a towing vehicle. .

However, if the tip (bucket 5C) of the work device 5 is at a position lower than the ground and the boom raising solenoid valve 25 constituting the solenoid valve device 23 is damaged, the boom 5A is lifted by the boom cylinder 5D. Since the lifting operation cannot be performed, the tip of the bucket 5C cannot be lifted above the ground. In this case, since the bucket 5C is caught on the ground, the hydraulic excavator 1 cannot be self-propelled to the trailer, nor can the hydraulic excavator 1 be moved using a towing vehicle.

On the other hand, in the present embodiment, among the plurality of solenoid valves constituting the solenoid valve device 23, the boom raising solenoid valve 25 related to the operation of lifting the boom 5A is mounted on the right side frame 9 of the revolving frame 6 in a side view. It is placed in a position that overlaps with the As a result, even if an external impact such as falling rocks acts on the upper rotating body 4 and damages part of the solenoid valve device 23 or the solenoid valve controller 27, etc., the right side frame 9, which is a strength member, will keep the boom up. The lifting solenoid valve 25 can be protected.

When the boom raising solenoid valve 25 is thus protected, the external controller 33 is connected to the boom raising solenoid valve 25 as shown in FIG. As a result, the boom 5A can be lifted using the external controller 33 even in an emergency when electrical components such as the solenoid valves other than the boom raising solenoid valve 25 and the solenoid valve controller 27 are damaged.

That is, the external controller 33 is electrically connected via the cable 34 to the boom raising solenoid valve 25 of the solenoid valve device 23 . An actuator drive lever 35 is connected to the external controller 33 , and the external controller 33 calculates a target valve opening degree of the boom raising electromagnetic valve according to the operation of the actuator drive lever 35 . Then, the external controller 33 increases or decreases the current value output to the electromagnetic pilot section of the boom electromagnetic valve according to the calculated target value of the valve opening. As a result, the valve opening degree of the boom solenoid valve is adjusted, and the pilot pressure supplied to the hydraulic pilot portion of the directional control valve for the boom cylinder 5D among the directional control valves forming the control valve 20 is controlled.

Therefore, the extension operation of the boom cylinder 5D is controlled according to the operation of the actuator drive lever 35, and by lifting the boom 5A, it is possible to prevent the bucket 5C from catching on the ground. In this state, for example, by moving the excavator 1 to a trailer using a towing vehicle, the excavator 1 can be loaded on the trailer and transported to a repair shop or the like. Instructions to the external controller 33 are not limited to being issued by operating the actuator operating lever 35 connected to the external controller 33. For example, instead of the actuator operating lever 35, wired communication or wireless communication using a portable terminal is performed. You may do so.

Thus, even if the solenoid valves other than the boom raising solenoid valve 25 or the solenoid valve controller 27 in the solenoid valve device 23 are damaged, by connecting the external controller 33 to the boom raising solenoid valve 25, the boom 5A can be operated. can be lifted to move the hydraulic excavator 1 . In this case, with the solenoid valve device 23 mounted on the revolving frame 6, the boom raising solenoid valve 25 is arranged at a height position intersecting the horizontal plane passing through the upper end 9E of the right side frame 9 (see FIG. 7). . As a result, when connecting the external controller 33 to the boom raising solenoid valve 25 via the cable 34, the operator can perform the connection work at a height position corresponding to the upper end 9E of the right side frame 9. The workability can be improved.

Thus, in the embodiment, the upper swing body 4 includes a base swing frame 6 and a plurality of hydraulic actuators (left travel motor 2A, right travel motor 2B, swing motor 3A, boom cylinder 5D, arm cylinder 5E) from the hydraulic pump 12. , bucket cylinder 5F), and an electric operating device (operating device 29 for left traveling, operating device 30 for right traveling, left A working operating device 31, a right working operating device 32), and an electromagnetic valve device 23 for controlling the control valve 20 based on an electric signal from the electric operating device. In a construction machine having a center frame 7 and a left side frame 8 and a right side frame 9 arranged on both left and right sides of the center frame 7, the plurality of hydraulic actuators form part of a working device 5. It includes a boom actuator (boom cylinder 5D) that vertically rotates the boom 5A with respect to the upper rotating body 4, and the solenoid valve device 23 is for raising the boom that causes the boom actuator to lift the boom 5A. It is composed of an assembly of a plurality of solenoid valves including the solenoid valve 25, and the boom raising solenoid valve 25 is arranged at a position overlapping the side frame (right side frame 9) in a side view.

According to this configuration, even if an external impact such as a collision with an obstacle or a falling rock acts on the upper rotating body 4, the right side frame 9, which is a strength member, keeps the boom-up solenoid valve 25 in place. can be protected. Therefore, for example, by connecting the external controller 33 to the boom raising solenoid valve 25, the boom raising solenoid valve 25 can be controlled using the external controller 33, and the extension operation of the boom cylinder 5D can be controlled. Therefore, the hydraulic excavator 1 can be moved by lifting the boom 5A and lifting the tip of the bucket 5C above the ground.

In the embodiment, the boom raising solenoid valve 25 is arranged at a height position intersecting a horizontal plane passing through the upper end 9</b>E of the right side frame 9 . According to this configuration, in addition to protecting the boom raising solenoid valve 25 by the right side frame 9 against an external impact acting on the upper rotating body 4 due to falling rocks or the like, the electromagnetic valve other than the boom raising solenoid valve 25 is protected. In an emergency when electrical components such as valves and the electromagnetic valve controller 27 are damaged, workability can be improved when connecting the external controller 33 to the boom raising electromagnetic valve 25 via the cable 34 .

In the embodiment, the electromagnetic valve device 23 is arranged on the front side of the attachment portion (boom attachment portion 7D) of the swing frame 6 to the boom 5A. The boom raising solenoid valves 25 are arranged in a plurality of rows in the longitudinal direction of the vehicle body while overlapping in a plurality of stages. According to this configuration, even if an impact such as falling rocks acts on the front side of the upper rotating body 4 during excavation work, the right front frame portion 9B and other solenoid valves arranged in front of the boom raising solenoid valve 25 will The boom raising solenoid valve 25 can be protected.

In the embodiment, the upper revolving body 4 has an open position in which the solenoid valve device 23 is exposed to the outside of the upper revolving body 4 and a closed position in which the solenoid valve device 23 is accommodated inside the upper revolving body 4 (valve accommodating chamber 19). A movable opening/closing cover (right front side cover 18E) is provided. According to this configuration, by closing the right front side cover 18E, the electromagnetic valve device 23 can be protected from flying stones and the like during excavation work. On the other hand, by setting the right front side cover 18E to the open position, it is possible to improve the workability when performing maintenance on the solenoid valve device 23 .

In this embodiment, the side frames are composed of a left side frame 8 arranged on the left side of the center frame 7 and a right side frame 9 arranged on the right side of the center frame 7. The right side frame 9 is the center frame. 7 and a right front frame portion 9B bent toward the center frame 7 from the front end of the right frame portion 9A. It is arranged inside the right front corner portion 9C where the frame portion 9B intersects. According to this configuration, the right frame portion 9A has high strength against force acting in the front-rear direction, and the right front frame portion 9B has high strength against force acting in the left-right direction. has great strength against impact from the outside. Therefore, the electromagnetic valve device 23 arranged inside the right front corner portion 9C can be protected with great strength.

Next, FIG. 10 shows a second embodiment of the invention. A feature of the present embodiment resides in that a hydraulic operating device is provided for controlling the control valve by outputting a pilot pressure corresponding to the operation in order to control the traveling actuator. In addition, in this embodiment, the same code|symbol is attached|subjected to the same component as 1st Embodiment, and the description is abbreviate|omitted.

In FIG. 10, a left travel operation device 36 and a right travel operation device 37 constitute a hydraulic operation device and are operated to control the left travel motor 2A and the right travel motor 2B, which are travel actuators. The left travel operation device 36 and the right travel operation device 37 are provided on the driver's seat 15 in place of the left travel operation device 29 and the right travel operation device 30 as electric operation devices used in the first embodiment. placed on the front side.

The left travel operation device 36 has a pressure reducing pilot valve and a lever pedal 36A, and is provided between the directional control valve for the left travel motor 2A and the pilot pump 13, which constitute the control valve 20. FIG. The left travel operating device 36 reduces the pilot pressure according to the operation of the lever pedal 36A, and transfers this pilot pressure to the hydraulic pilot section provided in the direction control valve for the left travel motor 2A through the pilot pipe 36B. supply. As a result, pressure oil from the hydraulic pump 12 is supplied to the left travel motor 2A in accordance with the operation of the lever pedal 36A, and the left travel motor 2A is rotationally driven.

The right travel operation device 37 has a pressure reducing valve type pilot valve and a lever pedal 37A, and is provided between the directional control valve for the right travel motor 2B and the pilot pump 13 that constitute the control valve 20 . The right travel operation device 37 reduces the pilot pressure according to the operation of the lever pedal 37A, and transfers this pilot pressure to the hydraulic pilot section provided in the directional control valve for the right travel motor 2B through the pilot pipe line 37B. supply. As a result, pressure oil from the hydraulic pump 12 is supplied to the right travel motor 2B in accordance with the operation of the lever pedal 37A, and the right travel motor 2B is rotationally driven.

The solenoid valve device 38 is configured as a multiple valve including a swing motor solenoid valve, a boom solenoid valve, an arm solenoid valve, and a bucket solenoid valve. The solenoid valve device 38 is a hydraulic pilot portion of a directional control valve corresponding to the work actuator (the swing motor 3A, the boom cylinder 5D, the arm cylinder 5E, and the bucket cylinder 5F) among the plurality of directional control valves that constitute the control valve 20. , the pilot pressure from the pilot pump 13 is selectively supplied.

The solenoid valve controller 39 is electrically connected via cables 28 to a plurality of solenoid valves that constitute the solenoid valve device 38 . An input side of the electromagnetic valve controller 39 is electrically connected to a left work operation device 31 and a right work operation device 32 as electric operation devices. The solenoid valve controller 39 controls the solenoid valves (swing motor solenoid valve, boom valve, etc.) constituting the solenoid valve device 38 based on electric signals input in accordance with the operation of the left work operation device 31 and the right work operation device 32 . The target value of the valve opening degree of each of the electromagnetic valves (solenoid valve, arm solenoid valve, bucket solenoid valve) is calculated, and the current value output to the electromagnetic pilot portion of the solenoid valve is increased or decreased according to the target value.

The hydraulic excavator according to the present embodiment includes a left travel operating device 36 and a right travel operating device 37 as hydraulic operating devices operated when controlling the left traveling motor 2A and the right traveling motor 2B, which are hydraulic actuators for traveling. , and there is no particular difference from the hydraulic excavator 1 according to the first embodiment in terms of the configuration and effect of protecting the boom raising solenoid valve 25 .

Accordingly, in the hydraulic excavator according to the second embodiment, the left travel operation device 36 and the right travel operation device 37, which are operated when controlling the travel actuators (the left travel motor 2A and the right travel motor 2B), are hydraulically operated. It consists of a type operation device. Therefore, for example, even if the solenoid valves other than the boom raising solenoid valve 25 in the solenoid valve device 38 are damaged, the left travel motor 2A and the left travel motor 2A and the left travel motor 2A and The right traveling motor 2B can be driven. Therefore, by operating the left travel operation device 36 and the right travel operation device 37 while the boom 5A is lifted using the external controller 33, the hydraulic excavator is self-propelled to the trailer, loaded on the trailer, and quickly transported. can be transported to a repair shop, etc.

In the embodiment, the boom raising solenoid valve 25 is arranged at a height position intersecting the horizontal plane passing through the upper end 9E of the right side frame 9. As shown in FIG. However, the present invention is not limited to this, and the boom raising solenoid valve 25 may be arranged within a height range between the bottom plate 7A of the center frame 7 and the upper end 9E of the right side frame 9, for example.

Further, in the embodiment, the solenoid valve device 23 is composed of valve casings 23A and 23B arranged in two rows in the front-rear direction, and a plurality of solenoid valves respectively provided in the two valve casings 23A and 23B. However, the case where the boom raising solenoid valve 25 is provided in the valve casing 23B arranged on the rear side is illustrated. However, the present invention is not limited to this. For example, an electromagnetic valve having a plurality of valve casings arranged in three or more rows in the front-rear direction is used, and the boom is raised in the valve casing positioned on the rearmost side among the plurality of valve casings. It is also possible to adopt a configuration in which an electromagnetic valve is provided.

2 Undercarriage (body)
2A Left travel motor (actuator for travel)
2B Right travel motor (actuator for travel)
4 upper rotating body (body)
5 Work device 5D Boom cylinder (actuator for boom)
6 Revolving frame (body frame)
7 center frame 7D boom mounting portion 8 left side frame 9 right side frame 9A right frame portion 9B right front frame portion 9C right front corner portion 9E upper end 18E right front side cover (opening/closing cover)
20 Control valve 23, 38 Solenoid valve device 25 Solenoid valve for boom raising

Claims (6)

A self-propellable vehicle body, a working device provided on the vehicle body, and a plurality of hydraulic actuators for driving at least the working device,
The vehicle body includes a vehicle body frame as a base, a control valve that controls the flow of pressure oil supplied from a hydraulic pump to the plurality of hydraulic actuators, an electric operation device that outputs an electric signal according to operation, and the a solenoid valve device that controls the control valve based on an electric signal from an electric operating device;
In a construction machine in which the body frame includes a center frame extending in the front-rear direction and side frames arranged on both left and right sides of the center frame,
the plurality of hydraulic actuators include a boom actuator that vertically rotates a boom that constitutes a part of the work device with respect to the vehicle body;
The solenoid valve device is composed of an assembly of a plurality of solenoid valves including a boom raising solenoid valve that causes the boom actuator to lift the boom,
The construction machine according to claim 1, wherein the boom raising solenoid valve is arranged at a position overlapping the side frame in a side view. The plurality of hydraulic actuators include travel actuators that cause the vehicle body to travel,
2. The vehicle body is provided with a hydraulic operation device that is operated when controlling the travel actuator and outputs a pilot pressure corresponding to the operation to control the control valve. Construction equipment as described in . 3. The construction machine according to claim 1, wherein said boom raising solenoid valve is arranged at a height position intersecting a horizontal plane passing through upper ends of said side frames. The solenoid valve device is arranged on the front side of an attachment portion of the vehicle body frame to the boom,
The plurality of solenoid valves constituting the solenoid valve device are arranged in a plurality of rows in the longitudinal direction of the vehicle body while being stacked in a plurality of stages in the vertical direction,
3. The construction machine according to claim 1, wherein the boom raising solenoid valve is arranged on the rear side of the plurality of rows. 2. The vehicle body is provided with an open/close cover that moves between an open position exposing the electromagnetic valve device to the outside of the vehicle body and a closed position housing the electromagnetic valve device inside the vehicle body. Or the construction machine according to 2. The side frames are composed of a left side frame arranged on the left side of the center frame and a right side frame arranged on the right side of the center frame,
The right side frame has a right frame portion extending in the front-rear direction along the center frame, and a right front frame portion bent from a front end of the right frame portion toward the center frame,
3. The construction machine according to claim 1, wherein the solenoid valve device is arranged inside a right front corner portion where the right frame portion and the right front frame portion intersect.

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